Abstract
This paper describes some experiments the author would haveliked to carry out if he had started earlier in the origin-of-life field.The proposal is preceded by a hypothetical outline of the mainevents in the origin of life. According to this outline, the emergence oflife amounts to the transition between two kinds of chemistry: 1) cosmic chemistry, which is beginning to be understood and mostlikely provided the building blocks with which life was first constructed; and 2)biochemistry, the well-known set of enzyme-catalyzedmetabolic reactions that support all living organisms today and must havesupported the universal common ancestor, or LUCA, from which all known formsof life are derived. The pathway leading from one to the other of thosetwo chemistries may be divided into three stages, defined as the pre-RNA, RNA, and protein-DNA stages. A briefsummary of the events that may have occurred in these three stages and ofthe possible underlying mechanisms is given. It is emphasized that theseevents were chemical in nature and, especially, that theymust have prefigured present-day biochemical processes. Protometabolismand metabolism, it is argued, must have been congruent. With congruence as the underlying working hypothesis, threeproblems open to experimental investigation are considered: 1) the involvementof peptides and other multimers as catalysts of early biogenic chemistry;2) the participation of thioesters in primitive energy transactions;and 3) the influence of amino acids on the molecular selection of RNAmolecules.
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de Duve, C. A Research Proposal on the Origin Of Life. Closing Lecture given at the ISSOL Congress in Oaxaca, Mexico, on July 4, 2002. Orig Life Evol Biosph 33, 559–574 (2003). https://doi.org/10.1023/A:1025760311436
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DOI: https://doi.org/10.1023/A:1025760311436